West Lafayette, Indiana
March 6, 2008
A newly defined biochemical
pathway in plants may provide the scientific tools to design
plants that will yield larger quantities of alternative
transportation fuels than currently can be produced, according
to Purdue University
researchers.
The pathway moves materials that determine cell shape and size
through a system of signaling proteins, said Dan Szymanski
(photo), a plant geneticist and cellular biologist. By learning
more about the growth and development process, it may be
possible to engineer plants with improved properties such as
cell walls that are more massive or are more easily fermented in
the biofuel process.
"We expect that cell wall material will to be a major source of
biomass from plants designated for biofuel production,"
Szymanski said. "We need to learn more about how plant cells
control the quality and amount of cell wall material."
He and his research team investigated plant growth and cell wall
development from several scientific approaches in determining
the cascade of events that leads to changes in the cell wall.
They discovered that a protein called "SPIKE1" directs the
protein signaling pathway. They report their findings in "Early
Edition," the online publication of the journal Proceedings of
the National Academy of Sciences. The study also will be
published in the journal's March 11 print issue.
"Plant cells grow by expansion, which is cell wall synthesis
coupled with an increase in cell size," Szymanski said. "The key
questions we need to answer in trying to create plants more
valuable for biofuel production center on understanding how
plants integrate metabolism, cell growth and biomass
production."
To answer those questions and be able to engineer plants for
improved growth of biomass for alternative fuels, Szymanski and
other scientists must investigate molecular function.
Plant growth and cell wall development
"Our research is focused on
understanding signaling mechanisms," he said. "How does a cell
interpret multiple types of information and then translate that
information to a signal that says, 'Grow here, or modify or
reinforce the cell wall here.' Or how does a cell know to make
new cytoskeleton filaments at a certain time and place to define
regions of growth that determine the cell's shape and size?"
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A
Purdue research team is studying plant growth and
cell wall development. By investigating plant cells
at the molecular level, they may be able to design
plants that are better sources of alternative
transportation fuels. In these three slides, green
outlines the outer epidermal cells. The red is from
chloroplasts from the underlying cell layer. The
final slide shows cells of a mutant plant in which a
gene called SPIKE1 has been turned off. These mutant
cells form abnormally and the cell walls won't
properly adhere to each, resulting in holes in the
epidermis that you can see through. (Photo courtesy
of Dan Szymanski, Purdue University) |
Actin filaments comprise the cytoskeleton, which is the roadway
for delivery and recycling of materials that drive plant growth
and determine the cell shape and size. Actin is an abundant
protein in organisms that have multiple cells with nuclei.
SPIKE1 is a master regulator of many growth control pathways,
including the protein signaling pathway that produces the
cytoskeleton. Szymanski and his colleagues were able to
demonstrate that one of SPIKE1's functions is to control
production of actin filament, which defines localized cell
regions for delivery and recycling of growth materials.
"Wall construction in plants, just as in a road project, is a
coordinated effort," Szymanski said. "The supply and demand of
the materials needed for growth must be coordinated. The
question is, how do cells regulate this?"
The signaling pathway, headed by SPIKE1, is responsible for
organizing activities during construction - delivering materials
and recycling materials that are used during growth, he said.
After SPIKE1 initiates communication among proteins along the
pathway, actin filaments are produced and changes in cell shape
and size occur.
Cells also must coordinate with the activities of surrounding
cells that have different shapes and functions.
"Cell expansion occurs in a crowded, but accommodating
environment," Szymanski said. "As neighboring cells expand, this
growth intrudes upon a neighbor. SPIKE1 generates signals so
that cells can coordinate with neighboring cells' activities to
promote organized cell expansion and proper cell-to-cell
adhesion."
Szymanski and his colleagues used an altered version of the
mustard family laboratory plant Arabidopsis to study SPIKE1's
function and find the proteins that it activates and to which it
binds.
They found that when they created mutant plants by switching off
the SPIKE1 gene so that the function is lost, one result was
improper growth that manifested as holes in the leaf epidermis.
By studying the results of turning off various other protein
complexes in the pathway, Szymanski's team was able to follow
the sequence of events that occur during signaling.
They also found that plants in which the function of one of the
pathway's signaling proteins was altered resulted in mutants
that all looked alike, Szymanski said. This suggested that the
three major protein complexes the scientists investigated all
function in a common pathway. The Purdue research team confirmed
this by making double mutants - plants in which two of the
proteins had been switched off. One of the pathway's protein
complexes, called "WAVE," functions the same way in both humans
and Arabidopsis, and the SPIKE1 signaling pathway is likely to
function in other plants including rice and corn.
However, in other organisms with SPIKE1-like genes, switching
off the gene kills the organism. This lethality has made it
difficult for scientists to understand the function of SPIKE1
and comparable genes in other organisms, including humans. Since
Arabidopsis survives when SPIKE1 is disrupted, the Purdue team
was able to determine the signaling pathway.
The scientists hypothesize that SPIKE1 may both generate and
organize protein complex signaling, Szymanski said. They also
need to discover what activates SPIKE1. When the researchers
understand enough about the processes involved in plant cell
growth and development, then they may be able to design plants
that are bigger with more cell wall that can be processed into
biofuel.
"Learning more about SPIKE1 likely will help us gain a better
understanding of the mechanics and regulation involved with the
pathways that control cell architecture and development in
plants, and also may be relevant to animal and human growth and
development," Szymanski said.
The other researchers involved with this study were graduate
student Dipanwita Basu, postdoctoral students Jie Le and Taya
Zakharova, and research technician Eileen Mallery. All are in
the Purdue Department of Agronomy.
The National Science Foundation and the Purdue Agricultural
Research Program funded this project. |
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Plant geneticist Dan
Szymanski of the Purdue
Department of Agronomy is
leading a research team that has
defined a biochemical pathway
that may make it possible to
engineer plants with improved
properties, potentially leading
to better biofuel sources. The
scientists are particularly
interested in the signaling that
leads to cell growth and
development. (Purdue
Agricultural Communication
photo/Tom Campbell) |
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